~speedprog/mtg/mtg_card_detector.git

			@@ -1,26 +1,38 @@
			#include <stdio.h>
			#include <time.h>
			#include "network.h"
			#include "image.h"
			#include "data.h"
			#include "utils.h"

			#include "crop_layer.h"
			#include "connected_layer.h"
			#include "convolutional_layer.h"
			#include "maxpool_layer.h"
			#include "cost_layer.h"
			#include "normalization_layer.h"
			#include "freeweight_layer.h"
			#include "softmax_layer.h"
			#include "dropout_layer.h"

			network make_network(int n)
			network make_network(int n, int batch)
			{
			network net;
			net.n = n;
			net.batch = batch;
			net.layers = calloc(net.n, sizeof(void *));
			net.types = calloc(net.n, sizeof(LAYER_TYPE));
			net.outputs = 0;
			net.output = 0;
			#ifdef GPU
			net.input_cl = calloc(1, sizeof(cl_mem));
			net.truth_cl = calloc(1, sizeof(cl_mem));
			#endif
			return net;
			}

			void forward_network(network net, double *input)

			void forward_network(network net, float input, float truth, int train)
			{
			int i;
			for(i = 0; i < net.n; ++i){
			@@ -34,6 +46,15 @@
			forward_connected_layer(layer, input);
			input = layer.output;
			}
			else if(net.types[i] == CROP){
			crop_layer layer = (crop_layer )net.layers[i];
			forward_crop_layer(layer, input);
			input = layer.output;
			}
			else if(net.types[i] == COST){
			cost_layer layer = (cost_layer )net.layers[i];
			forward_cost_layer(layer, input, truth);
			}
			else if(net.types[i] == SOFTMAX){
			softmax_layer layer = (softmax_layer )net.layers[i];
			forward_softmax_layer(layer, input);
			@@ -44,16 +65,31 @@
			forward_maxpool_layer(layer, input);
			input = layer.output;
			}
			else if(net.types[i] == NORMALIZATION){
			normalization_layer layer = (normalization_layer )net.layers[i];
			forward_normalization_layer(layer, input);
			input = layer.output;
			}
			else if(net.types[i] == DROPOUT){
			if(!train) continue;
			dropout_layer layer = (dropout_layer )net.layers[i];
			forward_dropout_layer(layer, input);
			}
			else if(net.types[i] == FREEWEIGHT){
			if(!train) continue;
			freeweight_layer layer = (freeweight_layer )net.layers[i];
			forward_freeweight_layer(layer, input);
			}
			}
			}

			void update_network(network net, double step, double momentum, double decay)
			void update_network(network net)
			{
			int i;
			for(i = 0; i < net.n; ++i){
			if(net.types[i] == CONVOLUTIONAL){
			convolutional_layer layer = (convolutional_layer )net.layers[i];
			update_convolutional_layer(layer, step, momentum, decay);
			update_convolutional_layer(layer);
			}
			else if(net.types[i] == MAXPOOL){
			//maxpool_layer layer = (maxpool_layer )net.layers[i];
			@@ -61,14 +97,17 @@
			else if(net.types[i] == SOFTMAX){
			//maxpool_layer layer = (maxpool_layer )net.layers[i];
			}
			else if(net.types[i] == NORMALIZATION){
			//maxpool_layer layer = (maxpool_layer )net.layers[i];
			}
			else if(net.types[i] == CONNECTED){
			connected_layer layer = (connected_layer )net.layers[i];
			update_connected_layer(layer, step, momentum, decay);
			update_connected_layer(layer);
			}
			}
			}

			double *get_network_output_layer(network net, int i)
			float *get_network_output_layer(network net, int i)
			{
			if(net.types[i] == CONVOLUTIONAL){
			convolutional_layer layer = (convolutional_layer )net.layers[i];
			@@ -79,18 +118,27 @@
			} else if(net.types[i] == SOFTMAX){
			softmax_layer layer = (softmax_layer )net.layers[i];
			return layer.output;
			} else if(net.types[i] == DROPOUT){
			return get_network_output_layer(net, i-1);
			} else if(net.types[i] == FREEWEIGHT){
			return get_network_output_layer(net, i-1);
			} else if(net.types[i] == CONNECTED){
			connected_layer layer = (connected_layer )net.layers[i];
			return layer.output;
			} else if(net.types[i] == NORMALIZATION){
			normalization_layer layer = (normalization_layer )net.layers[i];
			return layer.output;
			}
			return 0;
			}
			double *get_network_output(network net)
			float *get_network_output(network net)
			{
			return get_network_output_layer(net, net.n-1);
			int i;
			for(i = net.n-1; i > 0; --i) if(net.types[i] != COST) break;
			return get_network_output_layer(net, i);
			}

			double *get_network_delta_layer(network net, int i)
			float *get_network_delta_layer(network net, int i)
			{
			if(net.types[i] == CONVOLUTIONAL){
			convolutional_layer layer = (convolutional_layer )net.layers[i];
			@@ -101,6 +149,10 @@
			} else if(net.types[i] == SOFTMAX){
			softmax_layer layer = (softmax_layer )net.layers[i];
			return layer.delta;
			} else if(net.types[i] == DROPOUT){
			return get_network_delta_layer(net, i-1);
			} else if(net.types[i] == FREEWEIGHT){
			return get_network_delta_layer(net, i-1);
			} else if(net.types[i] == CONNECTED){
			connected_layer layer = (connected_layer )net.layers[i];
			return layer.delta;
			@@ -108,34 +160,49 @@
			return 0;
			}

			double *get_network_delta(network net)
			float get_network_cost(network net)
			{
			if(net.types[net.n-1] == COST){
			return ((cost_layer *)net.layers[net.n-1])->output[0];
			}
			return 0;
			}

			float *get_network_delta(network net)
			{
			return get_network_delta_layer(net, net.n-1);
			}

			void calculate_error_network(network net, double *truth)
			float calculate_error_network(network net, float *truth)
			{
			double *delta = get_network_delta(net);
			double *out = get_network_output(net);
			int i, k = get_network_output_size(net);
			for(i = 0; i < k; ++i){
			float sum = 0;
			float *delta = get_network_delta(net);
			float *out = get_network_output(net);
			int i;
			for(i = 0; i < get_network_output_size(net)*net.batch; ++i){
			//if(i %get_network_output_size(net) == 0) printf("\n");
			//printf("%5.2f %5.2f, ", out[i], truth[i]);
			//if(i == get_network_output_size(net)) printf("\n");
			delta[i] = truth[i] - out[i];
			//printf("%.10f, ", out[i]);
			sum += delta[i]*delta[i];
			}
			//printf("\n");
			return sum;
			}

			int get_predicted_class_network(network net)
			{
			double *out = get_network_output(net);
			float *out = get_network_output(net);
			int k = get_network_output_size(net);
			return max_index(out, k);
			}

			void backward_network(network net, double input, double truth)
			void backward_network(network net, float *input)
			{
			calculate_error_network(net, truth);
			int i;
			double *prev_input;
			double *prev_delta;
			float *prev_input;
			float *prev_delta;
			for(i = net.n-1; i >= 0; --i){
			if(i == 0){
			prev_input = input;
			@@ -146,54 +213,106 @@
			}
			if(net.types[i] == CONVOLUTIONAL){
			convolutional_layer layer = (convolutional_layer )net.layers[i];
			learn_convolutional_layer(layer, prev_input);
			if(i != 0) backward_convolutional_layer(layer, prev_input, prev_delta);
			backward_convolutional_layer(layer, prev_input, prev_delta);
			}
			else if(net.types[i] == MAXPOOL){
			maxpool_layer layer = (maxpool_layer )net.layers[i];
			if(i != 0) backward_maxpool_layer(layer, prev_input, prev_delta);
			if(i != 0) backward_maxpool_layer(layer, prev_delta);
			}
			else if(net.types[i] == NORMALIZATION){
			normalization_layer layer = (normalization_layer )net.layers[i];
			if(i != 0) backward_normalization_layer(layer, prev_input, prev_delta);
			}
			else if(net.types[i] == SOFTMAX){
			softmax_layer layer = (softmax_layer )net.layers[i];
			if(i != 0) backward_softmax_layer(layer, prev_input, prev_delta);
			if(i != 0) backward_softmax_layer(layer, prev_delta);
			}
			else if(net.types[i] == CONNECTED){
			connected_layer layer = (connected_layer )net.layers[i];
			learn_connected_layer(layer, prev_input);
			if(i != 0) backward_connected_layer(layer, prev_input, prev_delta);
			backward_connected_layer(layer, prev_input, prev_delta);
			}
			else if(net.types[i] == COST){
			cost_layer layer = (cost_layer )net.layers[i];
			backward_cost_layer(layer, prev_input, prev_delta);
			}
			}
			}

			int train_network_datum(network net, double x, double y, double step, double momentum, double decay)



			float train_network_datum(network net, float x, float y)
			{
			forward_network(net, x);
			int class = get_predicted_class_network(net);
			backward_network(net, x, y);
			update_network(net, step, momentum, decay);
			return (y[class]?1:0);
			forward_network(net, x, y, 1);
			//int class = get_predicted_class_network(net);
			backward_network(net, x);
			float error = get_network_cost(net);
			update_network(net);
			//return (y[class]?1:0);
			return error;
			}

			double train_network_sgd(network net, data d, int n, double step, double momentum,double decay)
			float train_network_sgd(network net, data d, int n)
			{
			int batch = net.batch;
			float X = calloc(batchd.X.cols, sizeof(float));
			float y = calloc(batchd.y.cols, sizeof(float));

			int i;
			int correct = 0;
			float sum = 0;
			for(i = 0; i < n; ++i){
			int index = rand()%d.X.rows;
			correct += train_network_datum(net, d.X.vals[index], d.y.vals[index], step, momentum, decay);
			//if((i+1)%10 == 0){
			// printf("%d: %f\n", (i+1), (double)correct/(i+1));
			//}
			get_random_batch(d, batch, X, y);
			float err = train_network_datum(net, X, y);
			sum += err;
			}
			return (double)correct/n;
			free(X);
			free(y);
			return (float)sum/(n*batch);
			}

			void train_network(network net, data d, double step, double momentum, double decay)
			float train_network_batch(network net, data d, int n)
			{
			int i,j;
			float sum = 0;
			int batch = 2;
			for(i = 0; i < n; ++i){
			for(j = 0; j < batch; ++j){
			int index = rand()%d.X.rows;
			float *x = d.X.vals[index];
			float *y = d.y.vals[index];
			forward_network(net, x, y, 1);
			backward_network(net, x);
			sum += get_network_cost(net);
			}
			update_network(net);
			}
			return (float)sum/(n*batch);
			}

			float train_network_data_cpu(network net, data d, int n)
			{
			int batch = net.batch;
			float X = calloc(batchd.X.cols, sizeof(float));
			float y = calloc(batchd.y.cols, sizeof(float));

			int i;
			float sum = 0;
			for(i = 0; i < n; ++i){
			get_next_batch(d, batch, i*batch, X, y);
			float err = train_network_datum(net, X, y);
			sum += err;
			}
			free(X);
			free(y);
			return (float)sum/(n*batch);
			}

			void train_network(network net, data d)
			{
			int i;
			int correct = 0;
			for(i = 0; i < d.X.rows; ++i){
			correct += train_network_datum(net, d.X.vals[i], d.y.vals[i], step, momentum, decay);
			correct += train_network_datum(net, d.X.vals[i], d.y.vals[i]);
			if(i%100 == 0){
			visualize_network(net);
			cvWaitKey(10);
			@@ -201,7 +320,35 @@
			}
			visualize_network(net);
			cvWaitKey(100);
			printf("Accuracy: %f\n", (double)correct/d.X.rows);
			fprintf(stderr, "Accuracy: %f\n", (float)correct/d.X.rows);
			}

			int get_network_input_size_layer(network net, int i)
			{
			if(net.types[i] == CONVOLUTIONAL){
			convolutional_layer layer = (convolutional_layer )net.layers[i];
			return layer.hlayer.wlayer.c;
			}
			else if(net.types[i] == MAXPOOL){
			maxpool_layer layer = (maxpool_layer )net.layers[i];
			return layer.hlayer.wlayer.c;
			}
			else if(net.types[i] == CONNECTED){
			connected_layer layer = (connected_layer )net.layers[i];
			return layer.inputs;
			} else if(net.types[i] == DROPOUT){
			dropout_layer layer = (dropout_layer ) net.layers[i];
			return layer.inputs;
			}
			else if(net.types[i] == FREEWEIGHT){
			freeweight_layer layer = (freeweight_layer ) net.layers[i];
			return layer.inputs;
			}
			else if(net.types[i] == SOFTMAX){
			softmax_layer layer = (softmax_layer )net.layers[i];
			return layer.inputs;
			}
			return 0;
			}

			int get_network_output_size_layer(network net, int i)
			@@ -220,6 +367,14 @@
			connected_layer layer = (connected_layer )net.layers[i];
			return layer.outputs;
			}
			else if(net.types[i] == DROPOUT){
			dropout_layer layer = (dropout_layer ) net.layers[i];
			return layer.inputs;
			}
			else if(net.types[i] == FREEWEIGHT){
			freeweight_layer layer = (freeweight_layer ) net.layers[i];
			return layer.inputs;
			}
			else if(net.types[i] == SOFTMAX){
			softmax_layer layer = (softmax_layer )net.layers[i];
			return layer.inputs;
			@@ -227,12 +382,50 @@
			return 0;
			}

			int resize_network(network net, int h, int w, int c)
			{
			int i;
			for (i = 0; i < net.n; ++i){
			if(net.types[i] == CONVOLUTIONAL){
			convolutional_layer layer = (convolutional_layer )net.layers[i];
			resize_convolutional_layer(layer, h, w, c);
			image output = get_convolutional_image(*layer);
			h = output.h;
			w = output.w;
			c = output.c;
			}else if(net.types[i] == MAXPOOL){
			maxpool_layer layer = (maxpool_layer )net.layers[i];
			resize_maxpool_layer(layer, h, w, c);
			image output = get_maxpool_image(*layer);
			h = output.h;
			w = output.w;
			c = output.c;
			}else if(net.types[i] == NORMALIZATION){
			normalization_layer layer = (normalization_layer )net.layers[i];
			resize_normalization_layer(layer, h, w, c);
			image output = get_normalization_image(*layer);
			h = output.h;
			w = output.w;
			c = output.c;
			}else{
			error("Cannot resize this type of layer");
			}
			}
			return 0;
			}

			int get_network_output_size(network net)
			{
			int i = net.n-1;
			int i;
			for(i = net.n-1; i > 0; --i) if(net.types[i] != COST) break;
			return get_network_output_size_layer(net, i);
			}

			int get_network_input_size(network net)
			{
			return get_network_input_size_layer(net, 0);
			}

			image get_network_image_layer(network net, int i)
			{
			if(net.types[i] == CONVOLUTIONAL){
			@@ -243,6 +436,14 @@
			maxpool_layer layer = (maxpool_layer )net.layers[i];
			return get_maxpool_image(layer);
			}
			else if(net.types[i] == NORMALIZATION){
			normalization_layer layer = (normalization_layer )net.layers[i];
			return get_normalization_image(layer);
			}
			else if(net.types[i] == CROP){
			crop_layer layer = (crop_layer )net.layers[i];
			return get_crop_image(layer);
			}
			return make_empty_image(0,0,0);
			}

			@@ -258,35 +459,83 @@

			void visualize_network(network net)
			{
			image *prev = 0;
			int i;
			char buff[256];
			//show_image(get_network_image_layer(net, 0), "Crop");
			for(i = 0; i < net.n; ++i){
			sprintf(buff, "Layer %d", i);
			if(net.types[i] == CONVOLUTIONAL){
			convolutional_layer layer = (convolutional_layer )net.layers[i];
			visualize_convolutional_filters(layer, buff);
			prev = visualize_convolutional_layer(layer, buff, prev);
			}
			if(net.types[i] == NORMALIZATION){
			normalization_layer layer = (normalization_layer )net.layers[i];
			visualize_normalization_layer(layer, buff);
			}
			}
			}

			double network_predict(network net, double input)
			void top_predictions(network net, int k, int *index)
			{
			forward_network(net, input);
			double *out = get_network_output(net);
			int size = get_network_output_size(net);
			float *out = get_network_output(net);
			top_k(out, size, k, index);
			}


			float network_predict(network net, float input)
			{
			forward_network(net, input, 0, 0);
			float *out = get_network_output(net);
			return out;
			}

			matrix network_predict_data_multi(network net, data test, int n)
			{
			int i,j,b,m;
			int k = get_network_output_size(net);
			matrix pred = make_matrix(test.X.rows, k);
			float X = calloc(net.batchtest.X.rows, sizeof(float));
			for(i = 0; i < test.X.rows; i += net.batch){
			for(b = 0; b < net.batch; ++b){
			if(i+b == test.X.rows) break;
			memcpy(X+btest.X.cols, test.X.vals[i+b], test.X.colssizeof(float));
			}
			for(m = 0; m < n; ++m){
			float *out = network_predict(net, X);
			for(b = 0; b < net.batch; ++b){
			if(i+b == test.X.rows) break;
			for(j = 0; j < k; ++j){
			pred.vals[i+b][j] += out[j+b*k]/n;
			}
			}
			}
			}
			free(X);
			return pred;
			}

			matrix network_predict_data(network net, data test)
			{
			int i,j;
			int i,j,b;
			int k = get_network_output_size(net);
			matrix pred = make_matrix(test.X.rows, k);
			for(i = 0; i < test.X.rows; ++i){
			double *out = network_predict(net, test.X.vals[i]);
			for(j = 0; j < k; ++j){
			pred.vals[i][j] = out[j];
			float X = calloc(net.batchtest.X.cols, sizeof(float));
			for(i = 0; i < test.X.rows; i += net.batch){
			for(b = 0; b < net.batch; ++b){
			if(i+b == test.X.rows) break;
			memcpy(X+btest.X.cols, test.X.vals[i+b], test.X.colssizeof(float));
			}
			float *out = network_predict(net, X);
			for(b = 0; b < net.batch; ++b){
			if(i+b == test.X.rows) break;
			for(j = 0; j < k; ++j){
			pred.vals[i+b][j] = out[j+b*k];
			}
			}
			}
			free(X);
			return pred;
			}

			@@ -294,7 +543,7 @@
			{
			int i,j;
			for(i = 0; i < net.n; ++i){
			double *output = 0;
			float *output = 0;
			int n = 0;
			if(net.types[i] == CONVOLUTIONAL){
			convolutional_layer layer = (convolutional_layer )net.layers[i];
			@@ -308,6 +557,12 @@
			image m = get_maxpool_image(layer);
			n = m.hm.wm.c;
			}
			else if(net.types[i] == CROP){
			crop_layer layer = (crop_layer )net.layers[i];
			output = layer.output;
			image m = get_crop_image(layer);
			n = m.hm.wm.c;
			}
			else if(net.types[i] == CONNECTED){
			connected_layer layer = (connected_layer )net.layers[i];
			output = layer.output;
			@@ -318,8 +573,8 @@
			output = layer.output;
			n = layer.inputs;
			}
			double mean = mean_array(output, n);
			double vari = variance_array(output, n);
			float mean = mean_array(output, n);
			float vari = variance_array(output, n);
			fprintf(stderr, "Layer %d - Mean: %f, Variance: %f\n",i,mean, vari);
			if(n > 100) n = 100;
			for(j = 0; j < n; ++j) fprintf(stderr, "%f, ", output[j]);
			@@ -328,11 +583,20 @@
			}
			}

			double network_accuracy(network net, data d)
			float network_accuracy(network net, data d)
			{
			matrix guess = network_predict_data(net, d);
			double acc = matrix_accuracy(d.y, guess);
			float acc = matrix_accuracy(d.y, guess);
			free_matrix(guess);
			return acc;
			}

			float network_accuracy_multi(network net, data d, int n)
			{
			matrix guess = network_predict_data_multi(net, d, n);
			float acc = matrix_accuracy(d.y, guess);
			free_matrix(guess);
			return acc;
			}